Power offloading for a subscriber line interface circuit

ABSTRACT

A power offload network has a node for receiving at least one supply V1. The power offload network includes at least one switch and a power offload element providing a supply drop of VR. The switch is configurable for selecting a linefeed supply level from the set including {V1, V1-VR}. A subscriber line interface circuit receives the selected linefeed supply level for driving a subscriber line.

FIELD OF THE INVENTION

This invention relates to methods and apparatus for managing power fordevices requiring supply levels that may vary, for example, inaccordance with device operational state.

BACKGROUND OF THE INVENTION

A subscriber line interface circuit typically requires different powersupply levels depending upon operational state. One supply level isrequired when the subscriber equipment is “on-hook” and another supplylevel is required when the subscriber equipment is “off-hook”. Yetanother supply level is required for “ringing”.

In order to ensure sufficient supply levels, a power supply providing aconstant or fixed supply level sufficient to meet or exceed therequirements of all of these states may be provided. Such a solutionpermits one or more SLICs to use a common power supply for at least twooperational states.

One disadvantage of a shared fixed power supply architecture is thatexcess power is generated and must be dissipated as heat or otherwisewasted when a SLIC is not using a power supply level optimized for itsparticular operational state or for the particular line conditions. Forexample, the power supply must be capable of supporting the worst-casescenario such as a maximum subscriber line length provided for byspecification. In the event the subscriber line is considerably shorterthan the maximum expected length, the SLIC will be required to absorbthe excess power. The resulting additional thermal load can beproblematic for integrated circuits of the SLIC.

One alternative to sharing fixed power supplies is to provide a trackingpower supply for each device. Each tracking power supply varies itssupply level in accordance with the requirements of its associateddevice. This tracking power supply architecture is more power efficientthan the shared fixed power supply architecture. Given that every deviceneeds its own tracking power supply, however, the tracking power supplyper device architecture may not be economical for a large number ofSLICs.

SUMMARY OF THE INVENTION

In one embodiment, a power offload network has a node for receiving atleast one supply V1. The power offload network includes at least oneswitch and a power offload element providing a supply drop of VR. Theswitch is configurable for selecting a linefeed supply level from theset including {V1, V1-VR}. A subscriber line interface circuit receivesthe selected linefeed supply level for driving a subscriber line.

In one embodiment, a power offload network has a first node forreceiving a first supply V1 and a second node for receiving a secondsupply V2. The power offload network includes a plurality of switchesand a power offload element providing a supply drop of VR. The switchesare configurable for selecting a linefeed supply level from the setincluding {V1, V2, V1-VR, V2-VR}. A subscriber line interface circuitreceives the selected linefeed supply level for driving a subscriberline.

In various embodiments, the switch(es) are configured to select thelinefeed supply level in accordance with at least one of a subscriberline condition and a SLIC operational state.

Other features and advantages of the present invention will be apparentfrom the accompanying drawings and from the detailed description thatfollows below.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is illustrated by way of example and notlimitation in the figures of the accompanying drawings, in which likereferences indicate similar elements and in which:

FIG. 1 illustrates one embodiment of a subscriber line interfacecircuit.

FIG. 2 illustrates one embodiment of power offload network.

FIG. 3 illustrates one embodiment of a method for configuring a poweroffload network having a plurality of supplies.

FIG. 4 illustrates one embodiment of a power offload network for asingle supply.

FIG. 5 illustrates one embodiment of a method for configuring a poweroffload network having at least one supply.

FIG. 6 illustrates an alternative embodiment of a power offload network.

DETAILED DESCRIPTION

FIG. 1 illustrates one embodiment of a subscriber line interface circuit110 associated with plain old telephone services (POTS) telephone lines.The subscriber line interface circuit (SLIC) provides an interfacebetween a digital switching network of a local telephone company centralexchange and a subscriber line comprising a tip 192 and a ring 194 line.A subscriber loop 190 is formed when the subscriber line is coupled tosubscriber equipment 160 such as a telephone.

The subscriber loop 190 communicates analog data signals (e.g.,voiceband communications) as well as subscriber loop “handshaking” orcontrol signals. The subscriber loop state is often specified in termsof the tip 192 and ring 194 portions of the subscriber loop.

The SLIC is typically expected to perform a number of functions oftencollectively referred to as the BORSCHT requirements. BORSCHT is anacronym for “battery feed,” “overvoltage protection,” “ring,”“supervision,” “codec,” “hybrid,” and “test.” The term “linefeed” willbe used interchangeably with “battery feed”. Modern SLICs may havebattery backup, but the supply to the subscriber line is typically notactually provided by a battery.

The ring function, for example, enables the SLIC to signal thesubscriber equipment 160. In one embodiment, subscriber equipment 160 isa telephone. Thus, the ring function enables the SLIC to ring thetelephone.

In the illustrated embodiment, the BORSCHT functions are distributedbetween a signal processor 120 and a linefeed driver 130. Signalprocessor 120 is responsible for at least the ring control, supervision,codec, and hybrid functions. Signal processor 120 controls andinterprets the large signal subscriber loop control signals as well ashandling the small signal analog voiceband data and the digitalvoiceband data.

In one embodiment, signal processor 120 is an integrated circuit. Theintegrated circuit includes sense inputs for both a sensed tip and asensed ring signal of the subscriber loop. The integrated circuitgenerates subscriber loop linefeed driver control signal in response tothe sensed signals. The signal processor has relatively low powerrequirements and can be implemented in a low voltage integrated circuitoperating in the range of approximately 5 volts or less.

Signal processor 120 receives subscriber loop state information fromlinefeed driver 130 as indicated by tip/ring sense 116. This informationis used to generate linefeed driver control 114 signals for linefeeddriver 130. Analog voiceband 112 data is bi-directionally communicatedbetween linefeed driver 130 and signal processor 120.

SLIC 110 includes a digital network interface 140 for communicatingdigitized voiceband data to the digital switching network of the publicswitched telephone network (PSTN). The SLIC may also include a processorinterface 150 to enable programmatic control of the signal processor120. The processor interface effectively enables programmatic or dynamiccontrol of battery control, battery feed state control, voiceband dataamplification and level shifting, longitudinal balance, ringingcurrents, and other subscriber loop control parameters as well assetting thresholds including ring trip detection and off-hook detectionthreshold.

Linefeed driver 130 maintains responsibility for battery feed to tip 192and ring 194. The battery feed and supervision circuitry typicallyoperate in the range of 40-75 volts. In some implementations the ringingfunction is handled by the same circuitry as the battery feed andsupervision circuitry. In other implementations, the ringing function isperformed by higher voltage ringing circuitry (75-150 V_(rms)).

Linefeed driver 130 modifies the large signal tip and ring operatingconditions in response to linefeed driver control 114 provided by signalprocessor 120. This arrangement enables the signal processor to performprocessing as needed to handle the majority of the BORSCHT functions.For example, the supervisory functions of ring trip, ground key, andoff-hook detection can be determined by signal processor 120 based onoperating parameters provided by tip/ring sense 116.

The linefeed driver receives a linefeed supply VBAT for driving thesubscriber line for SLIC “on-hook” and “off-hook” operational states. Analternate linefeed supply (ALT VBAT) may be provided to handle thehigher voltage levels (75-150 V_(rms)) associated with ringing.

VBAT may be provided as a fixed supply level. Typically VBAT is sharedamong a plurality of SLICs. Each SLIC is associated with its ownsubscriber line. The line conditions may vary greatly from onesubscriber line to another. One subscriber line may be considerablyshorter than another, for example. Shorter length subscriber loopsrequire less power to drive. VBAT, however, is selected to accommodate aworst-case scenario for driving the subscriber line. Excess power mustbe dissipated by the SLIC. Excess power results in an increased thermalload that may be problematic when the increased thermal load is carriedby an integrated circuit.

FIG. 2 illustrates one embodiment of a power offload network 220 thatmay be used with SLIC applications. The power offload network has afirst node 240 for receiving a first supply level, V1 and a second node242 for receiving a second supply level, V2. In one embodiment, thefirst and second supplies are substantially independent. Thus althoughV1 and V2 may be derived from a common source, V1 and V2 are independentof each other (i.e., neither V1 nor V2 is derived from the other). Thepower offload network includes a power offload element 224 and aplurality of switches. In the illustrated embodiment, transistors 226and 228 function as switches.

For a two supply application, the plurality of switches includes firstand second switches. A first terminal of the first switch 226 isconnected to the first node 240. A first terminal of the second switch228 is connected to a second terminal of the first switch 226. The poweroffload element is coupled in parallel with the second switch. The firstterminal of the second switch is diode-coupled (diode 222) to the secondnode 242. The linefeed supply is taken from the second terminal of thesecond switch.

The power offload network provides a supply level VOUT to integratedcircuit 210. In one embodiment, integrated circuit 210 forms a portionof a subscriber line interface circuit and VOUT is a linefeed supplylevel. Although a portion of the power offload network 220 may bedisposed within the integrated circuit 210, the power offload element224 is external to the integrated circuit. The switches can beconfigured to permit offloading at least some of the excess power to thepower offload element for consumption. The resulting thermal energy isalso dissipated by the power offload element rather than the integratedcircuit.

In the illustrated embodiment, a portion of the power offload network islocated within the integrated circuit 210. In particular, transistors226 and 228 are fabricated within the integrated circuit 210 andelectrically coupled to the remainder of the power offload networkthrough integrated circuit package pins such as pin 212.

Switches 226 and 228 may be controlled to select one of the two supplylevels or one of the two supply levels reduced in magnitude by thevoltage drop across the power offload element. This effectively permitsfour different supply levels from two supplies. Moreover, the cost ofthe components 222 and 224 are relatively small such that supply levelsV1 and V2 may be shared with a plurality of integrated circuits, eachintegrated circuit having its own power offload network.

In order for diode 222 to protect the power supplies, node 240 iscoupled to receive V1 and node 242 is coupled to receive V2 where V1<V2.In one embodiment of a SLIC application, V1≈−100V and V2≈−26V.Transistors 226 and 228 may be switched to provide four different supplylevels for VOUT. In the illustrated embodiment, N-typemetal-oxide-semiconductor transistors are used as switches. Inalternative embodiments, other transistor types may be used as switches.

In one embodiment, the gates of transistors 226 and 228 are controlledby bits A and B of a memory element such as register 214. Other types ofmemory or control lines may be used for controlling these switches.

Using the symbol “0” to denote that the transistor is not permitting anysubstantial conduction (i.e., “off”) and “1” to denote that thetransistor is permitting substantial conduction (i.e., “on”), thefollowing supply levels can be realized as indicated by Table 250 ofFIG. 2: A B VOUT 0 0 V2-VR 0 1 V2 1 0 V1-VR 1 1 V1

Generally, bit A controls selection between power supplies V1 and V2.Bit B determines whether the power offload element is selected to absorbexcess power. Thus values for bits A and B can be changed in accordancewith static or dynamic line conditions, operational state of theintegrated circuit, or even in response to the thermal status ofintegrated circuit 210 (i.e., enable power offload if the integratedcircuit temperature exceeds a pre-determined threshold). The use of amemory element such as a register permits programmatic control of thepower offload network.

In the illustrated embodiment, the power offload element comprises aresistor. VR is dependent upon the resistance of the resistor as well asthe supply level selected. The power offload element is selectable andprovides a non-zero voltage drop VR when selected.

Bit A may be dynamically changed to switch between V1 when ringing, forexample, and V2 when on-hook or off-hook. Bit B may be changed tofurther reduce (in magnitude) the supply level by VR to accommodate lineconditions such as short loop as necessary. Bit A may be considered acoarse selector for selecting the supply. Bit B further reduces thesupply level by VR when selected. Thus V1 might be selected for longloop ring while V1-VR is selected for short loop ringing. Similarly, V2might be selected for on-hook and long loop off-hook operational stateswhile V2-VR is selected for short loop off-hook SLIC operational statesand subscriber line conditions.

FIG. 3 illustrates one embodiment of a method for offloading power. Apower offload network coupled to receive a first supply V1 and a secondsupply V2 is provided in step 310. The power offload network includes aplurality of switches and a power offload element providing a voltagedrop VR. The switches are configurable to permit selecting a linefeedsupply level from the set {V1, V1-VR, V2, V2-VR}.

A subscriber line interface circuit receives the selected linefeedsupply level for driving a subscriber line in step 320. In step 330, theswitches are configured to select the linefeed supply level inaccordance with at least one of a subscriber line condition and a SLICoperational state. One switch, for example, may be controlled by thesubscriber line condition while another switch is controlled by a SLICoperational state.

The power offload network may be extended to include more than twosupplies. A power offload network may alternatively be utilized in asingle supply application.

FIG. 4 illustrates one embodiment of a single supply power offloadnetwork 420. The power offload network has a node 442 for receiving asupply level, V1. The power offload network includes a power offloadelement 424 and a switch. In the illustrated embodiment, transistor 428functions as a switch.

The power offload network provides a supply level VOUT to integratedcircuit 410. In one embodiment, integrated circuit 410 forms a portionof a subscriber line interface circuit and VOUT is a linefeed supplylevel. The power offload element 424 is external to the integratedcircuit. In the illustrated embodiment, the switch (i.e., transistor428) is fabricated within the integrated circuit 410 and electricallycoupled to the remainder of the power offload network through integratedcircuit package pins such as pin 412.

In the illustrated embodiment the switch is controlled by an associatedbit A of register 414. Switch 428 selects VOUT from the set {V1, V1-VR}where VR is a supply drop provided by the power offload element. Thevalue for bit A can be changed in accordance with static or dynamic lineconditions, operational state of the integrated circuit, or even inresponse to the thermal status of the integrated circuit (i.e.,magnitude of VOUT is decreased if the integrated circuit exceeds atemperature threshold). VR may be zero when the power offload element isnot selected to prevent unnecessary power consumption. When the poweroffload element is selected, however, VR is non-zero.

Thus in one embodiment, the power offload network has a node forreceiving a supply V1. The power offload network includes a poweroffload element providing a supply drop of VR. A switch is configurableto select a linefeed supply level from the set including {V1, V1−VR}. ASLIC receives the selected linefeed supply level for driving asubscriber line. In various embodiments, the switch is configured inaccordance with an operational state of the SLIC or a subscriber linecondition.

FIG. 5 illustrates one embodiment of a method for configuring a poweroffload network having at least one supply. A power offload networkcoupled to receive at least one supply V1 is provided in step 510. Thepower offload network includes a switch and a power offload elementproviding a supply drop VR. The switch permits selecting a linefeedsupply level from the set including {V1, V1-VR}.

A SLIC receives the selected linefeed supply level for driving thesubscriber line in step 520. In step 530, the switch is configured toselect the linefeed supply level in accordance with at least one of thesubscriber line condition and the SLIC operational state. Thus V1-VRmight be selected for on-hook and short-loop off-hook while V1 isselected for long-loop off-hook subscriber line conditions and SLICoperational states.

The power offload element is embodied as a resistor in FIGS. 2 and 4.Alternative embodiments may include elements in addition to or in lieuof a resistor. For example, a regulator may be used to restrict thesupply level provided to the integrated circuit.

FIG. 6 illustrates an alternative embodiment of a power offload network620. The power offload network has a node 642 for receiving a supplylevel, V1. The power offload network includes a power offload element630 and a switch 628. In the illustrated embodiment, transistor 628functions as a switch. The power offload element comprises a zener diode632 regulating a transistor 634 that is coupled to receive V1.

The power offload network provides a supply level VOUT to integratedcircuit 610. In one embodiment, integrated circuit 610 forms a portionof a SLIC and VOUT is a linefeed supply level. For SLIC applications, V1is a negative supply. The power offload element 630 is external to theintegrated circuit.

In the illustrated embodiment, the switch 628 is controlled by anassociated bit A of register 614. Switch 628 selects VOUT from the set{V1, V1-VR} where VR is a supply drop provided by the power offloadelement 630.

When switch 628 is conducting, diode 622 ensures that the power offloadelement has no effect and thus VOUT=V1. When switch 628 is notconducting, however, VOUT=V1-VR where VR is the supply drop provided bythe power offload element. Zener diode 632 and transistor 634 absorb theexcess power.

In the preceding detailed description, the invention is described withreference to specific exemplary embodiments thereof. Variousmodifications and changes may be made thereto without departing from thebroader spirit and scope of the invention as set forth in the claims.The specification and drawings are, accordingly, to be regarded in anillustrative rather than a restrictive sense.

1. An apparatus comprising: a power offload network receiving at leastone supply V1, the power offload network including at least one switchand a power offload element providing a supply drop of VR, the switchconfigurable for selecting a linefeed supply level from the setincluding {V1, V1-VR}; and a subscriber line interface circuit coupledto receive the selected linefeed supply level for driving a subscriberline.
 2. The apparatus of claim 1 wherein the power offload networkreceives at least two supplies including V1 as a first supply and V2 asa second supply.
 3. The apparatus of claim 1 wherein the V1 supply isthe only supply.
 4. The apparatus of claim 1 wherein the power offloadelement comprises a resistor.
 5. The apparatus of claim 1 wherein thepower offload element comprises a transistor.
 6. The apparatus of claim1 wherein the power offload element comprises a diode.
 7. The apparatusof claim 1 wherein the power offload element is a regulator.
 8. Theapparatus of claim 1 wherein the switch resides within an integratedcircuit.
 9. The apparatus of claim 8 wherein the integrated circuit is acomplementary metal oxide semiconductor (CMOS) integrated circuit. 10.The apparatus of claim 8 wherein the switch is configured in accordancewith a thermal status of the integrated circuit.
 11. The apparatus ofclaim 1 wherein the switch is configured in accordance with at least oneof a subscriber line interface circuit operational state and subscriberline condition.
 12. A method of managing power supply levels comprisesthe steps of: a) providing a power offload network coupled to receive atleast one supply V1, wherein the power offload network includes at leastone switch and a power offload element providing a supply drop VR,wherein the switch is configurable to select a linefeed supply levelfrom the set including {V1,V1-VR}; and b) providing the selectedlinefeed supply to a subscriber line interface circuit for driving asubscriber line.
 13. The method of claim 12 further comprising: c)configuring the switch in accordance with a selected operational stateof the subscriber line interface circuit.
 14. The method of claim 13wherein the subscriber line interface circuit has a plurality ofoperational states including on-hook, off-hook, and ringing.
 15. Themethod of claim 12 comprising: c) configuring the switch in accordancewith a subscriber line condition.
 16. The method of claim 15 wherein thesubscriber line exhibits one of a long loop and a short loop subscriberline condition.
 17. The method of claim 12 further comprising: c)configuring the switch in accordance with at least one of a selectedoperational state of the subscriber line interface circuit and asubscriber line condition.
 18. The method of claim 12 furthercomprising: c) configuring the switch in accordance with a thermalstatus of an integrated circuit.
 19. The method of claim 18 wherein theswitch resides within the integrated circuit.
 20. The method of claim 12wherein the V1 supply is the only received supply.